BREAST PUMP AND SYSTEM OR PROGRAM FOR PUMPING BREASTS
There is a breastfeeding device having a microprocessor having a memory embedded therein that can be pre-programmed to have a plurality of different sucking cycles interspersed with periodic pauses. These different cycles and pauses allow for an accurate modeling of a woman breastfeeding a child. In addition, this system and process can also result in a pre-programmable breastfeeding pump, which creates a preset time for initialization and a preset schedule of a series of events for breastfeeding over a period of time such as over a 24 hour or 30 hour period of time so that the user can automatically use the breast pump without having to use any of the keys on the keyboard of the device. In at least one embodiment, the device including any software which can be programmed thereon, is configured to mimic or model itself towards a suction pattern of a child.
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This application is a non provisional application that claims priority under 35 U.S.C. 119e from provisional application Ser. No. 61/642,416 filed on May 3, 2012 the disclosure of which is hereby incorporated herein by reference in its entirety.
BACKGROUND OF THE INVENTIONThe invention relates to a breast pump and a system for pumping breasts. This system is configured to perform a plurality of steps which are configured to pump breast milk or other fluids from a breast.
SUMMARY OF THE INVENTIONIn at least one embodiment, there is a system and process that results in a breastfeeding device having a microprocessor having a memory embedded therein that can be pre-programmed to have a plurality of different sucking cycles interspersed with periodic pauses. These different cycles and pauses allow for an accurate modeling of a woman breastfeeding a child. In addition, this system and process can also result in a pre-programmable breastfeeding pump, which creates a preset time for initialization and a preset schedule of a series of events for breastfeeding over a period of time such as over a 24 hour or 30 hour period of time so that the user can automatically use the breast pump without having to use any of the keys on the keyboard of the device.
Other objects and features of the present invention will become apparent from the following detailed description considered in connection with the accompanying drawings which disclose at least one embodiment of the present invention. It should be understood, however, that the drawings are designed for the purpose of illustration only and not as a definition of the limits of the invention.
In the drawings, wherein similar reference characters denote similar elements throughout the several views:
Turning in detail to the drawings,
A keypad 4 is shown coupled to housing 2, wherein keypad 4 includes a plurality of keys which allow a user to selectively scroll through a number of options.
A screen such as a LCD screen having a front cover 5 and an electronic screen component 52 is shown disposed in housing 2. Buttons 4 and screen 52 is also shown in greater detail in
A controller which can be in the form of a microcontroller 50 is coupled to motherboard 12 as well and receives power from power supply 20. This controller can be any suitable type of controller which can be in the form of a Atmel AT91SAM7SE256. This type of controller is an ARM7TDMI based High-performance 32-bit RISC Microcontroller with Thumb extensions, −256K Bytes Flash, 32K Bytes SRAM, clock up to 48 MHz,—USB 2.0 Full Speed,—88 I/O Pins, Memory Controller, Reset Controller, Clock Generator, Debug Unit, Power Management Controller, Advanced Interrupt Controller, Periodic Interval Timer, Windowed Watchdog, Real-time Clock, 11 Peripheral DMA Controller Channels, 3-channel 16-bit Timer/Counters, 4-channel PWM, Two USARTs, Synchronous Serial Controller, Serial Peripheral Controller, 2wire Interface, 8-channel 10-bit ADC, 4 High-current Drive I/O lines.
This controller can be configured to perform a series of pre-programmed steps such as those shown in
Controller 50 is also coupled to, or in communication with a number of other components such as a LCD display 50, a buzzer or audio annunciator 54, a microphone 56, a USB or serial communication port 58. LCD display 52 is shown in greater detail in
In addition, coupled to the PCB or micro controller or microprocessor 50 is a motor 60 wherein motor 60 is configured as a pump which provides a blowing force out from valve or opening 3 or a suction pressure into opening 3. Motor 60 can be any suitable motor and is configured to provide this pneumatic pressure through valve 62, which is coupled to micro controller 50 and is configured to be controlled by micro controller 50. A suction output 64 is fluidly coupled to valve 62 and is configured to allow fluid such as air or other suitable fluids to flow through valve 62. This suction output 64 is configured to be in fluid communication with opening 3. In addition, a pressure sensor 66 is coupled to and in communication with micro controller 50. This pressure sensor is configured to determine how much fluid is being sucked as well as how much pressure is being applied to the suction output.
The second phase which is initiated in step S7 as indicated includes a range of 30-40 cycles per minute at 30% of full pressure or power lasting 7-10 seconds in a first setting in step S8, and then proceeds to a second setting in step S9 wherein the power or suction switches to 75% of maximum lasting 2 to 4 seconds. Then in step S10 a pause is periodically initiated. This pause creates the simulation of a child swallowing milk. This periodic pause can occur at preset intervals and can occur for a preset period of time. For example, this pause can be set between the first setting and the second setting, or this pause can be set at the end of the second setting in step S9. In step S11 the fourth setting, the process reverts back to step s8 where the system reverts back to 30% of maximum pressure for 7 to 10 seconds again. This pattern will repeat itself during the entire phase. This phase can extend for a predetermined period of time such as 1 minute, 5 minutes 10 minutes or even more than 10 minutes.
The effects of the periodic breaks in sucking create a situation wherein this pause setting (See
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- Less stress on the milk ducts and breast tissue;
- Less stress on the ligaments supporting the breast;
- Enhanced milk production by mimicking more closely the natural pattern of a baby feeding.
This process is shown by way of a graph as well which as shown in
For example, in this process, in step S20, the user presses a menu button at a period of time before the time to initiate the breastfeeding process. At this point, the user in step S21 can create a set of preset settings such as the time for initiation of a series of breastfeeding pumping exercises. For example, this series can be for example 10 or more different ½ hour sessions for breast pumping using the two phases outlined in
Next, in step S24 the user can press on keypad 4 to press start to initiate the program. This starts a timer or clock in step 25 wherein that time was created originally in step S21. The timer is set to either a particular day of the week or a particular time of day so that a user can then have the machine automatically pump milk.
For example, for those practicing in the orthodox faith, Shabbat is observed with severe restrictions on how a user can operate machinery or electronic devices. For example, the user may be restricted from pushing any buttons such as on an elevator or on a breast pump during the hours of Shabbat. The period of time for Shabbat is observed from a few minutes before sunset on Friday evening, until the appearance of three stars in the sky on Saturday night. Many rabbinical scholars have pointed out that these regulations of labor have something in common-they prohibit any activity that is creative, or that exercises control or dominion over one's environment. In addition,
many of these activities are also prohibited on the Jewish holidays listed in the Torah, although there are significant exceptions permitting carrying and preparing food under specific circumstances.
Next in step S26, the user can select or press exit or end to leave the machine dormant until the time that it automatically initiates in step S27. In step S27, the total cycle of the first phase and the second phase can initiate for a period of time such as for 5 minutes, 10 minutes 30 minutes or 40 minutes. In at least one embodiment, this cycle for pumping breast milk for 30 minutes would be executed every three hours until Saturday 10 P.M. when the Shabbat mode or preset mode would automatically shut off.
To preserve the strict adherence to Talmud law and orthodox beliefs, the system can be set or optionally restricted so that the Shabbat events cannot be adjusted when the Shabbat mode is activated. In step S28, the array of events such as the approximately 10 breastfeeding events can be listed on display 5 during the Shabbat period of time so that the user, without pressing any buttons, can read and review the schedule for using the device 1. In step S30, the time period ends so that the device returns to its normal non preprogrammed routine for the rest of the week. This device can then be automatically reactivated by automatically returning to step S27 at the start of the next Shabbat period of time.
Thus, this system results in a breastfeeding device that can be pre-programmed to have periodic pauses and different types of sucking cycles which allow for an accurate modeling of a woman breastfeeding a child. In at least one embodiment, the device including any software which can be programmed thereon, is configured to mimic or model itself towards a suction pattern of a child on a woman who is lactating, or in the process of breastfeeding. In addition, this system and process can also result in a pre-programmable breastfeeding pump, which creates a preset time for initialization and a preset schedule of a series of events for breastfeeding over a period of time such as over a 24 hour or 30 hour period of time so that the user can automatically use the breast pump without having to use any of the keys 4 on the keyboard.
At least one embodiment of the present invention has the capability to capture, retrieve and transmit data via GPRS, WIFI, BLUETOOTH, or ANY wireless communication devices. The data capture will be sent to a remote web server, where the data will be collected and stored. All data transfer will be encrypted to ensure proper security.
As shown in
The process for recording and reporting the information relating to a breast pump is shown in greater detail in
As indicated above, the breast pump 1 is configured to relay the following information into servers 82 and 84: 1) Milk flow; 2) Air flow; 3) Pumping sessions; 4) Usage log; 5) Vacuum strength; 6) remote control information; 7) custom suction patterns.
The milk flow data can be used for several analyses. It can be used to determine the amount of milk that the mother is producing, it can determine if sufficient milk is being produced, and it can make recommendations as to how to improve milk productivity. It provides a convenience to lactation nurse who can remotely monitor and communicate efficiently to the mothers who are lactating. It can also provide immediate intervention if something goes wrong.
The air flow data is collected to ensure that the pump is pumping at a consistent rate, and that the mother or person breast feeding is getting sufficient suction based on the settings that they feel comfortable with. The air flow can be remotely controlled to provide immediate assistance if the user is not using it correctly or is feeling uncomfortable.
The pumping sessions data will be used as a daily/monthly log to track and chart their usage. It will be useful to monitor the amount of usage vs the increase/decrease in milk production, to ensure that the user's do get the maximum benefit out of using a breast pump, and that lactation nurse will also use this data log to provide proper recommendation to diagnose if there is a problem.
The usage log will be similar to the pumping sessions, and it will serve as a chart to track the usage of the mothers. The usage log can also be programmed locally and remotely to the breast pump, for religious purposes to turn on automatically and shut off automatically to enable usage towards a certain demographic of users. (Shabbat mode)
The vacuum strength data is important for the machine to ensure that the mothers are getting the appropriate suction. The system will also self-calibrate with the server if the vacuum strength is not what it is supposed to be set at. Vacuum strength can also be manually remote controlled if and when the mothers have issue with the machine and do not know what to do with it. The lactation nurse will remote control the vacuum strength.
The two-way remote control will be a two-way data communication which enables the machine to be controlled remotely, turning on/off, increasing/decreasing pressure, programming the auto/Shabbat mode. It also enables the lactation nurse to analyze data of the mother's usage to make sure she is getting the most out of using a breast pump.
In addition, there can be a customization of a suction pattern. For example, for certain mothers, the suction pattern of each child might be different. The remote control feature will enable lactation nurse or lactation technologist to program accordingly to the child's suck swallow pattern. This enables the mother to feel comfortable and ensure continuous milk flow.
Thus, this system is configured to create a breast pump that can have its activity pre-programmed so that the user does not have to push an excessive amount of buttons. In addition, the system is configured to create a breast pump that can be used to record the usage of the breast pump into a computer network so that the system can relay back to the user the information relating to the usage so that the user can view the quality of the breast pumping session.
Accordingly, while at least one embodiment of the present invention have been shown and described, it is to be understood that many changes and modifications may be made thereunto without departing from the spirit and scope of the invention as defined in the appended claims.
Claims
1. A breast pump comprising:
- a) a pump housing;
- b) a pump disposed in said pump housing;
- c) at least one reservoir;
- d) at least one feeding tube coupled to said pump housing, said feeding tube configured to feed fluid into said reservoir;
- e) at least one first filter configured to filter said fluid in said feeding tube;
- f) at least one second filter configured to filter said fluid in said feeding tube, said second filter being a different filter from said first filter.
2. The breast pump as in claim 1, wherein said at least one first filter and said at least one second filter is removable.
3. The breast pump as in claim 1, wherein said reservoir is removable.
4. The breast pump as in claim 1, further comprising at least one wireless transceiver configured to communicate with a computer network.
5. The breast pump as in claim 4, further comprising at least one microprocessor.
6. The breast pump as in claim 5, wherein said microprocessor is configured to record the amount of milk flow produced by the pump.
7. The breast pump as in claim 5, wherein said microprocessor is configured to record the amount of air flow through the pump.
8. The breast pump as in claim 5, wherein said microprocessor is configured to record the vacuum strength through the pump.
9. The breast pump as in claim 5, wherein said microprocessor is configured to record a usage log for the pump.
10. The breast pump as in claim 5, wherein said microprocessor is configured to record and schedule a pumping session.
11. The breast pump as in claim 10, wherein said scheduled pumping session is configured to start pumping automatically once the scheduled pumping session starts.
12. The breast pump as in claim 10, wherein the microprocessor is configured to control the pumping session so that there are at least two different phases for pumping during the pumping session.
13. The breast pump as in claim 12, wherein said at least two different phases comprise at least a first phase comprising a first amplitude and a first frequency and at least a second phase comprising at least a second amplitude and at least a second frequency.
14. The breast pump as in claim 13, wherein said at least one first phase comprises an amplitude that is lower than said amplitude of said second phase.
15. The breast pump as in claim 13, wherein said first phase has at least two different settings and said second phase has at least two different settings.
16. A process for controlling and recording the actions of a breast pump comprising the following steps:
- a) querying a usage log to determine whether a pumping session has been scheduled;
- b) initiating a pumping session when a usage log determines that it is time to start pumping;
- c) recording an amount of milk flowing due to the breast pump pumping;
- d) storing information relating to the amount of milk flowing in a server; and
- e) reporting on the amount of milk flowing due to the breast pump pumping.
17. The process as in claim 16, further comprising the step of:
- recording an amount of air flow in the system due to the breast pump pumping.
18. The process as in claim 17, further comprising the step of recording a vacuum strength of the breast pump pumping.
19. A process for programming a breast pump comprising:
- a) setting a start time;
- b) setting a first phase for pumping;
- c) setting a second phase for pumping;
- d) setting a shut down time;
- e) storing said start time, said first phase, said second phase, and said shut down time in a database; and
- f) recalling said start time from said database to start a breast pump at a preset time.
20. The process as in claim 19, wherein said first phase has a first setting of amplitude and frequency for pumping, and wherein said second phase has a second setting of amplitude and frequency for pumping.
Type: Application
Filed: May 3, 2013
Publication Date: Apr 23, 2015
Patent Grant number: 9808563
Applicant: GENADYNE BIOTECHNOLOGIES, INC. (Hicksville, NY)
Inventors: Shahzad Saad Pirzada (Old Westbury, NY), Chien Ming Goh (Syosset, NY), Maria Elizabeth Lynch (Fort Lauderdale, FL)
Application Number: 14/398,341
International Classification: A61M 1/06 (20060101);